Lunarcrete

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Laboratory-determined properties for lunarcrete[1][2]
Compressive strength 39–75.7 N/mm2 (MPa)
Young's modulus 21.4 kN/mm2
Density 2.6 g/cm3
Temperature coefficient 5.4 × 10−6 K−1

Lunarcrete, also known as "mooncrete", an idea first proposed by Larry A. Beyer of the University of Pittsburgh in 1985, is a hypothetical construction aggregate, similar to concrete, formed from lunar regolith, that would reduce the construction costs of building on the Moon.[3] AstroCrete is a more general concept also applicable for Mars.

Ingredients[edit]

Only comparatively small amounts of Moon rock have been transported to Earth, so in 1988 researchers at the University of North Dakota proposed simulating the construction of such a material by using lignite coal ash.[3] Other researchers have used the subsequently developed lunar regolith simulant materials, such as JSC-1 (developed in 1994 and as used by Toutanji et al.) and LHS-1 (developed and produced by Exolith Lab).[4][5] Some small-scale testing, with actual regolith, has been performed in laboratories, however.[2]

The basic ingredients for lunarcrete would be the same as those for terrestrial concrete: aggregate, water, and cement. In the case of lunarcrete, the aggregate would be lunar regolith. The cement would be manufactured by beneficiating lunar rock that had a high calcium content. Water would either be supplied from off the Moon, or by combining oxygen with hydrogen produced from lunar soil.[2]

Lin et al. used 40g of the lunar regolith samples obtained by Apollo 16 to produce lunarcrete in 1986.[6] The lunarcrete was cured by using steam on a dry aggregate/cement mixture. Lin proposed that the water for such steam could be produced by mixing hydrogen with lunar ilmenite at 800 °C, to produce titanium oxide, iron, and water. It was capable of withstanding compressive pressures of 75 MPa, and lost only 20% of that strength after repeated exposure to vacuum.[7]

In 2008, Houssam Toutanji, of the University of Alabama in Huntsville, and Richard Grugel, of the Marshall Space Flight Center, used a lunar soil simulant to determine whether lunarcrete could be made without water, using sulfur (obtainable from lunar dust) as the binding agent. The process to create this sulfur concrete required heating the sulfur to 130–140 °C. After exposure to 50 cycles of temperature changes, from -27 °C to room temperature, the simulant lunarcrete was found to be capable of withstanding compressive pressures of 17MPa, which Toutanji and Grugel believed could be raised to 20MPa if the material were reinforced with silica (also obtainable from lunar dust).[8]

Casting and production[edit]

There would need to be significant infrastructure in place before industrial scale production of lunarcrete could be possible.[2]

The casting of lunarcrete would require a pressurized environment, because attempting to cast in a vacuum would simply result in the water sublimating, and the lunarcrete failing to harden. Two solutions to this problem have been proposed: premixing the aggregate and the cement and then using a steam injection process to add the water, or the use of a pressurized concrete fabrication plant that produces pre-cast concrete blocks.[2][9]

Lunarcrete shares the same lack of tensile strength as terrestrial concrete. One suggested lunar equivalent tensioning material for creating pre-stressed concrete is lunar glass, also formed from regolith, much as fibreglass is already sometimes used as a terrestrial concrete reinforcement material.[2] Another tensioning material, suggested by David Bennett, is Kevlar, imported from Earth (which would be cheaper, in terms of mass, to import from Earth than conventional steel).[9]

Sulfur based "Waterless Concrete"[edit]

This proposal is based on the observation that water is likely to be a precious commodity on the Moon. Also sulfur gains strength in a very short time and doesn't need any period of cooling, unlike hydraulic cement. This would reduce the time that human astronauts would need to be exposed to the surface lunar environment.[10][11]

Sulfur is present on the Moon in the form of the mineral troilite, (FeS)[12] and could be reduced to obtain sulfur. It also doesn't require the ultra high temperatures needed for extraction of cementitious components (e.g. anorthosites).

Sulfur concrete is an established construction material. Strictly speaking it isn't a concrete as there is little by way of chemical reaction. Instead the sulfur acts as a thermoplastic material binding with a non reactive substrate. Cement and water are not required. The concrete doesn't have to be cured, instead it is simply heated to above the melting point of sulfur, 140 °C, and after cooling it reaches high strength immediately.

The best mixture for tensile and compressive strength is 65% JSC-1 lunar regolith simulant and 35% sulfur, with an average compressive strength of 33.8 MPa and tensile strength of 3.7 MPa. Addition of 2% metal fiber increase the compressive strength to 43.0 MPa[13] Addition of silica also increases the strength of the concrete.[14]

This sulfur concrete could be of especial value for dust minimization, for instance to create a launching pad for rockets leaving the Moon.[12]

AstroCrete[edit]

Graphical abstract of AstroCrete concept

AstroCrete is a concrete-like material proposed to be used on Moon or Mars made from regolith and human serum albumin (HSA), a protein from human blood. Scientists demonstrated that such material had compressive strengths as high as 25 MPa, while ordinary concrete had 20–32 MPa. By adding urea (byproduct in urine, sweat, and tears), the resultant material became substantially stronger than ordinary concrete, with 40 MPa of compressive strength.[15][16][17]

As noted by the authors:[16]

In essence, human serum albumin produced by astronauts in vivo could be extracted on a semi-continuous basis and combined with lunar or Martian regolith to ‘get stone from blood’, to rephrase the proverb. We believe that human serum albumin extraterrestrial regolith biocomposites could potentially have a significant role in a nascent Martian colony.

Researchers also experimented with synthetic spider silk and bovine serum albumin as regolith binders, noting that these materials could also be produced on Mars after advancements in biomanufacturing technology.[16]

The idea behind AstroCrete is not new, that is acknowledged by authors: "adhesives and binders of biological origin were widely utilized by humanity for millennia before the development of synthetic petroleum-derived adhesives. Tree resins, collagen from hooves, casein from cheese, and animal blood were all used as binders and additives for various applications".[16]

Researchers calculated that a crew of 6 astronauts could produce over 500 kg of AstroCrete over the course of a two-year mission on the surface of Mars.[15] Each astronaut "could produce enough additional habitat space to support another astronaut, potentially allowing the steady expansion of an early Martian colony".[17]

  • Scheme depicting the typical fabrication procedure for producing HSA-based biocomposites
    Scheme depicting the typical fabrication procedure for producing HSA-based biocomposites
  • 3D-printed Astrocrete samples. (a) after fabrication, (b) during compression testing, and (c) after compression testing.
    3D-printed Astrocrete samples. (a) after fabrication, (b) during compression testing, and (c) after compression testing.
  • Life-cycle process flow diagram for HSA/Urea-based biocomposites
    Life-cycle process flow diagram for HSA/Urea-based biocomposites
  • A hypothetical block diagram depicting how HSA could be produced in vivo from in situ resources available on Mars
    A hypothetical block diagram depicting how HSA could be produced in vivo from in situ resources available on Mars

Issues with "Sulfur Concrete"[edit]

It provides less protection from cosmic radiation, so walls would need to be thicker than Portland-cement-based concrete walls (the water in concrete is an especially good absorber of cosmic radiation).

Sulfur melts at 115.2 °C, and lunar temperatures in high latitudes can reach 123 °C at midday. In addition, the temperature changes could change the volume of the sulfur concrete due to polymorphic transitions in the sulfur.[12] (see Allotropes of sulfur).[14]

So unprotected sulfur concrete on the Moon, if directly exposed to the surface temperatures, would need to be limited to higher latitudes or shaded locations with maximum temperatures less than 96 °C and monthly variations not exceeding 114 °C.

The material would degrade through repeated temperature cycles, but the effects are likely to be less extreme on the Moon due to the slowness of the monthly temperature cycle. The outer few millimeters may be damaged through sputtering from impact of high energy particles from the solar wind and solar flares. This may however be easy to repair, by reheating or recoating the surface layers in order to sinter away cracks and heal the damage.

Use[edit]

David Bennett, of the British Cement Association, argues that lunarcrete has the following advantages as a construction material for lunar bases:[9]

  • Lunarcrete production would require less energy than lunar production of steel, aluminium, or brick.[9]
  • It is unaffected by temperature variations of +120 °C to −150 °C.[9]
  • It will absorb gamma rays.[9]
  • Material integrity is not affected by prolonged exposure to vacuum. Although free water will evaporate from the material, the water that is chemically bound as a result of the curing process will not.[9]

He observes, however, that lunarcrete is not an airtight material, and to make it airtight would require the application of an epoxy coating to the interior of any lunarcrete structure.[9]

Bennett suggests that hypothetical lunar buildings made of lunarcrete would most likely use a low-grade concrete block for interior compartments and rooms, and a high-grade dense silica particle cement-based concrete for exterior skins.[9]

See also[edit]

References[edit]

  1. ^ J. A. Happel (1993). "Indigenous materials for lunar construction". Applied Mechanics Reviews. 46 (6). American Society of Mechanical Engineers: 313–325. Bibcode:1993ApMRv..46..313H. doi:10.1115/1.3120360.
  2. ^ a b c d e f F. Ruess; J. Schaenzlin & H. Benaroya (July 2006). "Structural Design of a Lunar Habitat" (PDF). Journal of Aerospace Engineering. 19 (3). American Society of Civil Engineers: 138. doi:10.1061/(ASCE)0893-1321(2006)19:3(133).
  3. ^ a b "UND Engineers Would Like to Follow the Lunarcrete Road". Grand Forks Herald. North Dakota. 1988-02-28.
  4. ^ Long-Fox, Jared; Lucas, Michael P.; Landsman, Zoe; Millwater, Catherine; Britt, Daniel; Neal, Clive (April 2022). Applicability of Simulants in Developing Lunar Systems and Infrastructure: Geotechnical Measurements of Lunar Highlands Simulant LHS-1. ASCE Earth and Space 2022. Denver, CO. p. 11. doi:10.1061/9780784484470.007.
  5. ^ H. Toutanji; M. R. Fiske & M. P. Bodiford (2006). "Development and Application of Lunar "Concrete" for Habitats". In Ramesh B. Malla; Wieslaw K. Binienda & Arup K. Maji (eds.). Proceedings of 10th Biennial International Conference on Engineering, Construction, and Operations in Challenging Environments (Earth & Space 2006) and 2nd NASA/ARO/ASCE Workshop on Granular Materials in Lunar and Martian Exploration held in League City/Houston, TX, during March 5–8, 2006. Reston, VA: American Society of Civil Engineers. pp. 1–8. doi:10.1061/40830(188)69. ISBN 0784408300.
  6. ^ François Spiero & David C. Dunand (1997). "Simulation of Martian Materials and Resources Exploitation on a Variable Gravity Research Facility". In Thomas R. Meyer (ed.). The Case for Mars IV: the international exploration of Mars — consideration for sending humans : proceedings of the fourth Case for Mars Conference held June 4–8, 1990, at the University of Colorado, Boulder, Colorado. Vol. 90. Univelt for the American Astronautical Society. p. 356. ISBN 9780877034216.
  7. ^ George William Herbert (1992-11-17). Norman Yarvin (ed.). "Luna concrete". Archives: Space: Science, Exploration.
  8. ^ Colin Barras (2008-10-17). "Astronauts Could Mix DIY Concrete for Cheap Moon Base". New Scientist.
  9. ^ a b c d e f g h i D. F. H. Bennett (2002). "Concrete: the material — Lunar concrete". Innovations in concrete. Thomas Telford Books. pp. 86–88. ISBN 0-7277-2005-8.
  10. ^ Performance of "Waterless Concrete" Houssam A. Toutanji Steve Evans Richard N. Grugel
  11. ^ PRODUCTION OF LUNAR CONCRETE USING MOLTEN SULFUR, Final Research Report for JoVe NASA Grant NAG8 - 278, Dr. Husam A. Omar Department of Civil Engineering University of South Alabama
  12. ^ a b c I. Casanova (1997). "Feasibility and Applications of Sulfur Concrete for Lunar Base Development: A Preliminary Study" (PDF). 28th Annual Lunar and Planetary Science Conference, March 17–21, 1997, Houston, TX. p. 209.
  13. ^ PRODUCTION OF LUNAR CONCRETE USING MOLTEN SULFUR Final Research Report for JoVe NASA Grant NAG8 - 278 by Dr. Husam A. Omar
  14. ^ a b Houssam Toutanji; Becca Glenn-Loper & Beth Schrayshuen (2005). "Strength and Durability Performance of Waterless Lunar Concrete". 43rd AIAA Aerospace Sciences Meeting and Exhibit 10 – 13 January 2005, Reno, Nevada. American Institute of Aeronautics and Astronautics. doi:10.2514/6.2005-1436.
  15. ^ a b "Affordable housing in outer space: Scientists develop cosmic concrete from space dust and astronaut blood". The University of Manchester. Retrieved 25 October 2021.
  16. ^ a b c d Roberts, A.D.; Whittall, D.R.; Breitling, R.; Takano, E.; Blaker, J.J.; Hay, S.; Scrutton, N.S. (September 2021). "Blood, sweat, and tears: extraterrestrial regolith biocomposites with in vivo binders". Materials Today Bio. 12: 100136. doi:10.1016/j.mtbio.2021.100136. PMC 8463914. PMID 34604732.
  17. ^ a b Blakemore, Erin (September 18, 2021). "Astronauts' bodily fluids might help build concrete-type shelters on other planets". Washington Post. Retrieved 25 October 2021.

Further reading[edit]

External links[edit]

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